JP2012192492A - Work tool - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a work tool that is effective for simplification and rationalization of a structure for mounting a dust collector to a work tool body.SOLUTION: The work tool has: a work tool body 103; a dust collector 120 detachably attached to the work tool body 103; a machine type engaging unit 151 for engaging the work tool body 103 with the dust collector 120 manually releasably; and a spacer member 157 for elastically supporting the work tool body 103 and the dust collector 120 between the work tool body 103 and the dust collector 120 in an engagement state of the machine type engaging unit 151.

Description

  The present invention relates to a work tool having a dust collecting device for collecting dust generated when performing a machining operation.

  European Patent Specification No. 1459842 (Patent Document 1) discloses a dust collector mounting structure that is detachably mounted on a tool body of a work tool that performs a processing operation such as a hammer operation or a hammer drill operation. The attachment structure of the dust collector described in the European Patent Specification includes a plurality of mechanical engagement parts including recesses and protrusions that can be engaged with each other at a plurality of positions spaced apart from each other by a predetermined distance. The configuration is such that the dust collector is attached to the work tool main body by engaging the recesses and the protrusions of the plurality of mechanical engagement portions, respectively, and in the engagement state of the plurality of mechanical engagement portions, the mechanical engagement The dust collector is locked (fixed) to the work tool body by a lock mechanism provided separately from the unit.

  According to the dust collector mounting structure described in European Patent Specification No. 1459842, the dust collector can be mounted on the work tool body, but there is still room for improvement in order to simplify and rationalize the structure. There is.

European Patent Specification No. 1459842

  The present invention has been made in view of the above, and an object of the present invention is to provide a work tool effective for simplifying and rationalizing a structure for attaching a dust collector to a work tool body.

  In order to achieve the above object, according to a preferred embodiment of the work tool according to the present invention, the work tool body, the dust collector that is detachably attached to the work tool body, and the work tool body and the dust collector are manually released. A mechanical engagement portion that freely engages, and a spacer member that elastically supports the work tool body and the dust collector between the work tool body and the dust collector in an engaged state of the mechanical engagement portion. Have Note that “engagement” in the present invention typically includes a concave portion and a protruding portion that can be engaged (fitted) with each other, and the concave portion and the protruding portion. A mode in which the working tool main body and the dust collecting device are connected by fitting each other into this corresponds to this. Further, the “elastic support” by the spacer member in the present invention means that a spacer member elastically biased by the elastic member is interposed between the work tool main body and the dust collecting device in a pressing manner, thereby The aspect which adjusts the clearance gap between the recessed part of a type | formula engaging part and a protruding part corresponds to this. In this case, the spacer member is preferably provided on the dust collector side.

  According to the present invention, since the work tool main body and the dust collector are elastically supported by the spacer member in a state where the work tool main body and the dust collector are engaged via the mechanical engagement portion. The backlash of the dust collector with respect to the work tool main body, which occurs when there is a gap in the mechanical engagement portion, can be suppressed by the spacer member. Thereby, a dust collector can be attached to a working tool main body in a stable state. Further, since the work tool main body and the dust collector are elastically supported by the spacer member between the work tool main body and the dust collector, for example, a plurality of mechanical engagement parts including concave parts and projecting parts are used. Thus, it is possible to construct a mounting structure that is structurally simplified compared to a configuration in which the dust collector is attached to the work tool body.

According to the further form of this invention, a work tool main body and a dust collector have the 1st opposing surface which mutually opposes, and the 2nd opposing surface which mutually opposes, and is mechanical on a 1st opposing surface. The engaging portion is disposed, and the spacer member is disposed on the second facing surface. Note that the first facing surface and the second facing surface may be in a relationship of being parallel to each other (positional relationship) or crossing each other.
According to this aspect, when the work tool main body and the dust collector rotate relative to each other with the mechanical engagement portion as a fulcrum, the relative rotation can be elastically supported by the spacer member.

According to the further form of this invention, the 1st opposing surface and the 2nd opposing surface are set in the position mutually spaced apart.
According to this aspect, when the work tool main body and the dust collector rotate relative to each other with the mechanical engagement portion as a fulcrum, the relative rotation can be elastically supported at a position away from the mechanical engagement portion. .

According to the further form of this invention, the spacer member is comprised by the wedge-shaped member supported elastically.
According to this aspect, the gap is rationally filled (packed) regardless of the size of the gap by elastically supporting the wedge-shaped member between the work tool main body and the dust collector so as to be elastically interposed. be able to.

According to the further form of this invention, the 1st opposing surface and the 2nd opposing surface are connected via the 3rd opposing surface.
According to this aspect, the third facing surface is interposed between the first facing surface and the second facing surface, so that the first facing surface and the second facing surface are separated from each other. Easy to set.

According to the further form of this invention, a mechanical engaging part is a guide groove extended linearly, and the guide rail fitted by moving relatively with respect to the said guide groove in the extension direction. And the fitting direction of the guide rail with respect to the guide groove coincides with the elastic supporting direction of the wedge.
According to this form, when the guide groove and the guide rail are moved relative to each other so that the dust collector is attached to the work tool body, the wedge-shaped member is interposed between the work tool body and the dust collector. It becomes possible to comprise. For this reason, it is possible to attach the dust collector to the work tool body with one touch, which is effective in simplifying the attaching operation.

According to the further form of this invention, it has a lock part which can lock the engagement state of a work tool main body and dust collector with a mechanical engagement part, and a lock release.
According to this aspect, it is possible to prevent an unexpected position shift or dropout of the dust collector with respect to the work tool main body.

  According to a further aspect of the present invention, a predetermined machining operation is performed on the workpiece by causing the tip tool mounted on the tip region of the work tool body to linearly move in the long axis direction and rotate around the long axis direction. A hammer drill is constructed. And the work tool main body is provided with the dust collector attachment area | region which enables the dust collector of any one of Claims 1-7 to be attached.

  According to the present invention, a work tool effective for simplification and rationalization of the structure for attaching the dust collector to the work tool body is provided.

It is side sectional drawing which shows the whole structure of the hammer drill with which the dust collection attachment which concerns on embodiment of this invention was attached. It is sectional drawing which shows the hammer drill from which the dust collection attachment was removed. It is sectional drawing which shows the whole structure of a dust collection attachment. It is a longitudinal cross-sectional view which shows the engaging mechanism part and locking mechanism of a dust collection attachment, and shows the locked state of a locking mechanism. It is a longitudinal cross-sectional view which shows the engaging mechanism part and locking mechanism of a dust collection attachment, and shows the lock release state of a locking mechanism. It is a longitudinal cross-sectional view which shows the engagement mechanism part and lock release lever of a dust collection attachment, and shows the non-operation state of a lock release lever. It is a longitudinal cross-sectional view which shows the engagement mechanism part and lock release lever of a dust collection attachment, and shows the time of release operation of a lock release lever.

  Hereinafter, embodiments of the present invention will be described in detail with reference to FIGS. In this embodiment, a rechargeable hammer drill will be described as an example of a work tool. As shown in FIG. 1 and FIG. 2, the hammer drill 101 of the present embodiment generally includes a main body portion 103 that forms an outline of the hammer drill 101, and a tool holder in a tip region (left side in the drawing) of the main body portion 103. A hammer bit 119 as a tip tool that is detachably attached via 118 and a hand grip 109 connected to the opposite side of the hammer bit 119 of the main body 103 are mainly configured. The main body 103 corresponds to the “work tool main body” in the present invention.

  The hand grip 109 is provided as a main handle that is gripped by the user. The hammer bit 119 is held by the tool holder 118 in a state where relative reciprocation in the major axis direction is possible and relative rotation in the circumferential direction is restricted. For convenience of explanation, the hammer bit 119 side is referred to as the front and the handgrip 109 side is referred to as the rear in a state where the main body 103 is placed in a direction in which the major axis direction of the hammer bit 119 is the horizontal direction.

  The main body 103 mainly includes a motor housing 105 that houses a drive motor 111, and a gear housing 107 that houses a motion conversion mechanism 113, a striking element 115, and a power transmission mechanism 117 as a drive mechanism. The motor housing 105 is disposed below the rear side of the gear housing 107 and is joined to the gear housing 107. The handgrip 109 extends in the vertical direction intersecting the major axis direction of the hammer bit 119, and the upper end and the lower end thereof are connected to the main body 103, whereby a loop handle (D-shaped handle). Is configured. A battery mounting portion 109A is formed at the lower end of the handgrip 109, and a rechargeable battery pack 110 serving as a power source for the drive motor 111 is detachably mounted on the battery mounting portion 109A.

  The rotational power of the drive motor 111 is appropriately converted into a linear motion by a motion conversion mechanism 113 composed mainly of a swash mechanism (oscillation mechanism) in which an oscillation ring oscillates, and then transmitted to the striking element 115. A striking force in the major axis direction (left-right direction in FIG. 1) is applied to the hammer bit 119 via the striking element 115. Further, the rotational power of the drive motor 111 is appropriately decelerated by a power transmission mechanism 117 mainly composed of a plurality of gears, and then transmitted to the hammer bit 119 via the tool holder 118 as a final shaft, thereby The hammer bit 119 is rotated in the circumferential direction. The drive motor 111 is arranged at the lower side of the hammer bit 119 in the major axis direction so that the extension line of the rotation axis crosses the major axis (long axis direction) of the hammer bit 119 and is arranged on the hand grip 109. When the operator pulls the trigger 109a, the energization is driven. The driving of the hammer bit 119 by the motion conversion mechanism 113, the striking element 115, and the power transmission mechanism 117 is a well-known technique and is not directly related to the present invention.

  Further, the hammer drill 101 is provided with a drill mode in which a hole is formed in a workpiece by applying only a rotational force around the long axis direction (circumferential direction) to the hammer bit 119 by an operator's operation, and in the long axis direction. It is possible to switch between a hammer drill mode in which a punching operation is performed on a workpiece by applying a striking force and a rotational force in the circumferential direction. This is a well-known technique and is also included in the present invention. Since is not directly related, its description is omitted.

  Next, a dust collection attachment 120 that is attached to the hammer drill 101 configured as described above and absorbs dust generated during processing on a workpiece (for example, concrete) will be described mainly with reference to FIG. To do. The dust collection attachment 120 corresponds to the “dust collection device” in the present invention.

  The dust collection attachment 150 according to the present embodiment is a suction source built-in system in which a dust collection motor 123 and a suction fan 125 as dust collection power sources are built in the attachment main body 121, respectively. The attachment main body 121 is detachably attached so as to overlap the attachment mounting portion in the lower front area of the main body 103 by moving horizontally from the front to the rear in the long axis direction of the hammer bit 119. It is supposed to be configured. The attachment structure of the dust collection attachment 120 will be described later.

  As shown in FIG. 2, the dust collection attachment 120 includes an attachment body 121, a dust suction unit 131, a dust transfer unit 137, a dust collection container 127, a suction fan 125, and a dust collection motor 123. When the suction fan 125 is rotationally driven by the dust collection motor 123, a suction force acts on the dust suction part 131 through the inside of the dust collection container 127 and the dust transfer part 137. Dust generated during the processing operation is sucked from the dust suction port 133a of the dust suction unit 131 by the suction force of the dust suction unit 131 and is collected in the dust collecting container 127 through the dust transfer unit 137.

  The attachment main body 121 is substantially L in a side view having a vertical region extending linearly downward from the rear end of the dust transfer unit 137 and a horizontal region extending rearward from the lower end of the vertical region. It is formed into a shape. The vertical region is provided as a container attachment portion 121A to which the dust collection container 127 is mounted, and the horizontal region is provided as a dust collection motor housing portion 121B that houses the dust collection motor 123.

  The dust collection motor 123 is arranged in the dust collection motor housing 121B with the rotation axis direction parallel to the major axis direction of the hammer bit 119 (the major axis direction of the dust transfer unit), and a suction fan arranged in front thereof A suction force is generated in the dust collecting container 127 by rotationally driving 125. This suction force acts on the dust suction part 131 from the dust container 127 through the dust transfer part 137.

  The dust collecting container 127 is formed in a substantially rectangular box shape, and is mounted in a state of being in contact with the vertical front surface of the container mounting portion 121A in the attachment main body 121 from the front, and the rear lower region of the dust transfer portion 137 Placed in. The dust collecting container 127 is detachably attached to the container attaching portion 121 </ b> A, and a dust filter 129 is accommodated in the dust collecting container 127. The dust collection container 127 discharges the air filtered through the dust suction opening 126 formed on the upper side and the dust filter 129 so as to suck the dust transferred through the internal passage of the dust transfer unit 137 into the inside. Therefore, it has an air outlet 128 formed on the lower side. The air discharge port 128 is set to face the suction fan 125.

  The dust suction part 131 has a substantially box-shaped suction cylinder part 133 whose front is opened as a dust suction port 133a, and extends downward from the suction cylinder part 133 intersecting the major axis direction of the hammer bit 119. The extended end portion has a hollow suction body portion 135 connected to the dust transfer portion 137. The suction cylinder portion 133 is a hammer bit that extends through the rear end wall portion 133b formed rearward to the front dust suction port 133a in a state where the dust collection attachment 120 is attached to the main body portion 103 of the hammer drill 101. 119 is provided as a dust suction member that covers (surrounds) the bit tip portion 119a (see FIG. 1) at a predetermined interval, and is pressed against the workpiece during processing. The dust sucked into the suction cylinder part 133 is transferred to the dust transfer part 137 through the inside of the suction body part 135.

  The dust transfer portion 137 connected to the suction body portion 135 extends in parallel with the long axis direction of the hammer bit 119 at a position spaced from the hammer bit 119 in a direction intersecting the long axis direction of the hammer bit 119. Yes. When a processing operation is performed on the workpiece by the hammer bit 119 in a state where the suction cylinder portion 133 is pressed against the workpiece together with the hammer bit 119, the work progresses (the hammer bit 119 enters the workpiece). Accordingly, it is necessary that the dust suction part 131 in which the suction cylinder part 133 is pressed against the workpiece is retracted relative to the hammer bit 119 toward the main body part 103 side.

  In order to enable the dust suction part 131 to move backward, the dust transfer part 137 is configured as an extendable dust transfer cylinder member extending in parallel with the hammer bit 119. The telescopic dust transfer unit 137 is composed of a movable cylinder part 137A and a fixed cylinder part 137B that are slidably fitted in the major axis direction, and the front end of the movable cylinder part 137A is connected to the suction body part 135. . The fixed cylinder portion 137B constitutes a part of the attachment main body 121. For this reason, the dust suction part 131 is configured to be connected to the attachment main body 121 via the dust transfer part 137 so as to be movable in the long axis direction of the hammer bit 119.

  A telescopic bellows-like hose 139 is disposed inside the movable cylinder part 137A and the fixed cylinder part 137B, and dust is transferred inside the hose 139. The hose 139 has a front end connected to the rear end of the suction body 135, a rear end connected to the rear end of the fixed cylinder 137B, and communicated with the dust suction opening 126 of the dust collecting container 127. . In addition, the dust transfer part 137 is always hold | maintained in the expansion | extension state (initial state) with the elastic force of the bellows shape area | region of the hose 139. As described above, the hose 139 is disposed inside the movable cylinder part 137A and the fixed cylinder part 137B, and the sliding surface between the movable cylinder part 137A and the fixed cylinder part 137B is configured to transfer dust inside the hose. It is possible to prevent the dust from being caught in the surface.

  Next, an attachment structure of the dust collecting attachment 120 configured as described above to the main body 103 of the hammer drill 101 will be described with reference mainly to FIGS. The dust collection attachment 120 is moved horizontally from the front to the rear of the main body 103 of the hammer drill 101 in the long axis direction of the hammer bit 119 so that it overlaps the front lower region of the main body 103 of the hammer drill 101. It can be attached in a suspended form.

  As shown in FIG. 2, the main body portion 103 of the hammer drill 101 has a lower surface 105 a of the motor housing 105, a front surface 105 b of the motor housing 105, and a front lower surface 107 a of the gear housing 107. A substantially Z-shaped attachment mounting seat is formed. Correspondingly, the attachment body 121 constitutes the upper surface 121b of the dust collection motor accommodating portion 121B constituting the horizontal region, the rear surface 121a of the container mounting portion 121A constituting the vertical region, and a part of the attachment body 121. A substantially Z-shaped attachment surface is formed in a side view by the upper surface 137b of the fixed cylinder portion 137B of the dust transfer portion 137.

  That is, the upper surface 121b of the dust collection motor housing 121B and the lower surface 105a of the motor housing 105 are set to face each other, and the two facing surfaces correspond to the “first facing surface” in the present invention. The rear surface 121a of the container mounting portion 121A and the front surface 105b of the motor housing 105 are set to face each other, and the two facing surfaces correspond to the “third facing surface” in the present invention. The upper surface 137b of the fixed cylinder portion 137B and the front lower surface 107a of the gear housing 107 are set to face each other, and the two facing surfaces correspond to the “second facing surface” in the present invention.

  An engagement for attaching the dust collection attachment 120 to the main body 103 of the hammer drill 101 between the upper surface 121b of the dust collection motor housing 121B of the dust collection attachment 120 and the lower surface 105a of the motor housing 105 constituting the main body 103. The mechanism unit 151 is set. As shown in FIG. 4 to FIG. 7, the engaging mechanism portion 151 is mainly configured by a pair of left and right guide grooves 153 as recessed portions that can be fitted to each other and a pair of left and right guide rails 155 as projecting portions. Has been. The engagement mechanism portion 151 corresponds to the “mechanical engagement portion” in the present invention.

  On the motor housing 105 side, a pair of left and right guide grooves 153 extending in a predetermined length in parallel with the long axis direction of the hammer bit 119 is formed. The left and right guide grooves 153 are formed in the left and right side lower regions of the motor housing 105 as substantially U-shaped cross-sections with open sides, and at least the front end in the extending direction is open. A pair of left and right guide rails 155 are formed on the dust collection motor housing 121B side. The left and right guide rails 155 are formed as inward flange-like members facing each other by bending the upper ends of the left and right side wall portions of the dust collection motor accommodating portion 121B by approximately 90 degrees. Accordingly, in a state where the rear end of the guide rail 155 and the front end of the guide groove 153 are aligned, the dust collection attachment 120 is moved in the major axis direction of the hammer bit 119 from the front to the rear of the main body 103 of the hammer drill 101. The guide rail 155 can be fitted into the guide groove 153 by relatively moving horizontally. Accordingly, the dust collection attachment 120 is supported in a suspended manner on the main body 103 side.

  On the other hand, on the upper surface 137b side of the fixed cylinder portion 137B, as shown in FIG. 3, the guide rail 155 of the engagement mechanism portion 151 is pressed against the front lower surface 107a of the gear housing 107 in a state where the guide rail 155 is fitted in the guide groove 153. Thus, a wedge-shaped member 157 that presses the main body portion 103 and the dust collection attachment 120 so as not to separate (fills up and down the gap between the guide rail 155 and the guide groove 153) is attached. The wedge-shaped member 157 corresponds to the “spacer member” in the present invention.

  On the upper surface 137b side of the fixed cylindrical portion 137B, a substantially rectangular storage box 159 having an opening formed on the rear side for storing the wedge-shaped member 157 is integrally formed with the fixed cylindrical portion 137B. The wedge-shaped member 157 housed in the housing box 159 is slidable in the longitudinal direction of the hammer bit 119 and is urged rearward in the longitudinal direction of the hammer bit 119 by a compression coil spring 161 as an urging member. In addition, the rear end portion protrudes rearward from the opening of the accommodation box 159. And the inclined surface 157a which inclines below toward the front end side is formed in the said projecting end part upper surface. That is, the wedge-shaped member 157 has an inclined facing surface that faces the front lower surface 107a of the gear housing 107 in the spring biasing direction. When the dust collection attachment 120 is removed from the main body 103, the wedge-shaped member 157 has a protrusion 157b formed on the lower surface on the front end side (rear end side) on the stopper 163 provided on the fixed cylinder portion 137B. It is restricted to the maximum projecting position by contacting.

  When the dust collection attachment 120 is moved horizontally relative to the rear of the main body 103 so that the guide rail 155 fits into the guide groove 153, the wedge-shaped member 157 has an inclined surface 157a at the front end of the gear housing 107. The main body 103 and the dust collection attachment 120 are supported in a resilient manner by being pressed in a resilient manner against the inclined outer surface portion 107b of the lower surface 107a. As a result, even if there is a gap in the vertical direction between the guide rail 155 and the guide groove 153, the wedge-shaped member 157 has a gap between the upper surface 137b of the fixed cylindrical portion 137B and the front lower surface 107a of the gear housing 107. By being interposed in a bullet shape, the engagement mechanism portion 151 is prevented from rattling. That is, the relative movement (relative rotation) in the vertical direction with the engaging mechanism portion 151 as a fulcrum is suppressed.

  In addition, a connector 141 is provided between the attachment main body 121 and the main body portion 103 to connect the electric wiring on the main body portion 103 side and the electric wiring on the dust collection attachment side. In the present embodiment, the connector 141B on the dust collection attachment side is a male connector formed by a protruding member that protrudes horizontally rearward from the rear end surface of the container attachment portion 121A of the attachment main body 121. The connector 141A on the side is a female connector formed by a concave member that is recessed horizontally in the rear in the front surface portion of the main body 103 (the motor housing 105). When the dust collection attachment 120 is moved horizontally from the front to the rear and attached to the main body 103, the male connector 141B is simultaneously inserted into the female connector 141A, and the electrical wiring terminals on the dust collection attachment side Is connected to the electric wiring terminal on the main body side. That is, when the dust collection attachment 120 is attached to the main body 103, the dust collection attachment 120 side and the main body 103 side are electrically connected, and when the drive motor 111 is energized by pulling the trigger 109a, the dust collection motor 123 is also configured to be energized at the same time.

  Further, as shown in FIGS. 4 to 7, when the dust collection attachment 120 is attached to the main body 103, the attachment state of the dust collection attachment 120 is fixed to the dust collection motor housing 121 </ b> B of the attachment body 121 ( A lock mechanism 165 for locking is provided. The lock mechanism 165 corresponds to the “lock portion” in the present invention. The lock mechanism 165 is mainly composed of a lock claw 167 and an unlock member 175. The lock claw 167 is a vertical direction that intersects the mounting direction (the fitting direction of the guide rail 155 with respect to the guide groove 153) of the dust collecting attachment 120 via the guide member 169 inside the upper side of the dust collecting motor accommodating portion 121B. It is normally urged by a compression coil spring 171 to project upward through an opening formed in the upper wall of the dust collection motor housing 121B. On the lower surface side of the motor housing 105, a lock hole 173 that is open at the lower side where the lock claw 167 can be engaged is formed.

  The lock claw 167 has an inclined surface 167a (see FIG. 3) formed at the front end portion (rear end portion) in the mounting direction. When the dust collecting attachment 120 is moved relative to the main body portion 103, the relative movement of the lock claw 167 is reduced. In the initial stage, the inclined surface 167 a is pressed by the lower surface 105 a of the motor housing 105 and moved downward against the urging force of the compression coil spring 171. When the dust collection attachment 120 is moved to a predetermined position and the relative movement with respect to the main body 103 is finished, the upper portion of the lock claw 167 faces the lock hole 173 of the motor housing 105, and the biasing force of the compression coil spring 171 is used. It is configured to move upward and engage with the lock hole 173. As a result, the dust collection attachment 120 is fixed (locked) to the main body 103 and the movement of the dust collection attachment 120 in the removal direction is restricted. This state is shown in FIG.

  As shown in FIGS. 6 and 7, the lock release member 175 is configured by a push button provided on the side wall portion of the dust collection motor housing portion 121 </ b> B so that it can be pushed horizontally from the outside. The unlocking member 175 has an arm portion 177 extending horizontally in the push-in direction toward the side surface of the lock claw 167, and an inclined surface 177 a is formed at the extending end of the arm portion 177. Correspondingly, an inclined surface 167 b facing the inclined surface 177 a of the arm portion 177 is formed on the side portion of the lock claw 167. Therefore, as shown in FIG. 7, when the unlocking member 175 is pushed in horizontally, the inclined surface 177a at the tip of the arm portion 177 presses the side inclined surface 167b of the lock claw 167, and the lock claw 167 Is moved downward. Thereby, the upper part of the lock claw 167 comes out of the lock hole 173, and the lock of the dust collection attachment 120 with respect to the main-body part 103 is cancelled | released. This state is shown in FIG. The lock release member 175 is urged in a direction away from the lock claw 167 by the compression coil spring 179, and is always held at the initial position. The unlocking member 175 placed at the initial position is set so that the pressing surface pressed by a finger is substantially flush with the side surface of the dust collection motor housing 121B.

  The present embodiment is configured as described above. When the dust collection attachment 120 is attached to the hammer drill 101, the rear ends of the left and right guide rails 155 of the dust collection motor housing portion 121B are arranged at the ends (front ends) of the left and right guide grooves 153 of the main body 103 (the motor housing 105). Adjust the position of. In this state, when the dust collection attachment 120 is relatively moved horizontally (moved to the right side in the drawing) in a direction approaching the main body 103 (rearward), the guide rail 155 is fitted in the guide groove 153. In the middle of the relative movement, the inclined surface 157a at the tip of the wedge-shaped member 157 in the moving direction comes into contact with the main body portion 103 (the inclined outer surface portion 107b of the front lower surface 107a of the gear housing 107. In this state, the dust collecting attachment 150 is attached to a predetermined position. When the relative movement is further performed to the position, the wedge-shaped member 157 moves relative to the attachment main body 121 forward (left side in the drawing) against the urging force of the compression coil spring 161, and with a predetermined pressing force against the main body 103. Pressed.

  Therefore, there is a vertical gap between the guide rail 155 and the guide groove 153, and the wedge-shaped member 157 is elastically interposed between the upper surface 137b of the fixed cylindrical portion 137B and the front lower surface 107a of the gear housing 107. Thus, the backlash of the engagement mechanism 151 is stopped. That is, the relative movement (rotation) in the vertical direction with the engaging mechanism portion 151 of the dust collection attachment 120 as a fulcrum is suppressed, and the attachment state of the dust collection attachment 120 to the main body portion 103 is stabilized.

  Further, since the wedge-shaped member 157 provided on the attachment main body 121 is elastically supported by pressing the main body portion 103 against the main body portion 103, the dust collection attachment 120 and the main body portion 103 are elastically supported. It is not necessary to perform special processing for attaching the attachment 120. From this, it is possible to construct a mounting structure that is structurally simplified compared to the conventional configuration in which the engagement mechanism portion 151 is set at a plurality of locations.

  Further, in the present embodiment, the fitting direction of the guide rail 155 with respect to the guide groove 153 coincides with the biasing direction of the wedge-shaped member 157 by the compression coil spring 161. For this reason, the attachment operation of the dust collection attachment 120 with respect to the main-body part 103 can be easily performed by one-touch operation by the relative movement of a horizontal direction (long axis direction of the hammer bit 119), and attachment operability can be improved.

  On the other hand, when attaching the dust collection attachment 120, the male connector 141B on the dust collection attachment 120 side is inserted into the female connector 141A on the main body 103 side, and the electrical wiring terminal on the dust collection attachment side is connected to the main body side. It is comprised so that it may be connected to the electrical wiring terminal. That is, according to the present embodiment, the attachment direction of the dust collection attachment 120 with respect to the main body 103 and the connection direction of the connector 141 are set to coincide. For this reason, based on the attachment operation | movement with respect to the main-body part 103 of the dust collection attachment 120, the connection operation | movement of the connector 141 is performed automatically.

  Further, when the dust collection attachment 120 is attached, as described above, the lock claw 167 is pressed against the urging force of the compression coil spring 171 by pressing the inclined surface 167a by the lower surface of the motor housing 105 in the initial stage of attachment. Moved. When the dust collection attachment 150 is relatively moved to the predetermined mounting position, that is, when it is placed at the final mounting position, the lock claw 167 passes through the lower surface of the motor housing 105 and faces the lock hole 173 of the motor housing 105. To do. For this reason, the lock claw 167 is moved upward by the urging force of the compression coil spring 171 and engages with the lock hole 173. As a result, the dust collection attachment 120 is fixed (locked) to the main body 103 and movement in the removal direction is restricted. That is, at the same time when the attachment operation of the dust collection attachment 120 to the main body 103 is completed, automatic locking by the lock mechanism 165 is performed.

  As described above, according to the present embodiment, with respect to the dust collection attachment 120, in the front of the main body 103 of the hammer drill 101, the positions of the guide rail 155 and the guide groove 153 are aligned and then the rear is approaching the main body 103. Can be attached so as to overlap the front lower region of the main body portion 103 of the hammer drill 101.

  When removing the dust collection attachment 120 from the main body 103, if the lock release member 175 is pushed in, the lock claw 167 is pressed downward against the compression coil spring 171 by the arm portion 177 of the lock release member 175. It is moved and comes out of the lock hole 173. Since the lock is released by this, the dust collection attachment 120 can be detached from the main body 103 by moving the dust collection attachment 120 forward from the main body 103 in this state.

  Further, according to the present embodiment, the guide rail 155 and the guide groove are provided between the upper surface 121b of the motor housing portion 121B and the lower surface 105a of the motor housing 105 of the main body portion 103 (between the first opposing surfaces). 153 is set between the upper surface 137b of the fixed cylinder portion 137B that also serves as a part of the attachment main body 121 facing each other and the front lower surface 107a of the gear housing 107 of the main body portion 103 (second A wedge-shaped member 157 is set between the opposing surfaces. As a result, the relative rotation in the vertical direction about the engaging mechanism portion 151 of the dust collecting attachment 120 with respect to the main body portion 103 can be elastically supported by the wedge-shaped member 157 at a position away from the engaging mechanism portion 151. . In this case, since the rear surface 121a of the container mounting portion 121A facing each other and the front surface 105b (third facing surface) of the motor housing 105 are interposed between the first facing surface and the second facing surface, the first facing This is effective in setting the positional relationship between the surface and the second facing surface apart from each other.

  Note that this embodiment can be modified as appropriate. For example, the guide rail 155 may be provided in the main body 103 (the motor housing 105), and the guide groove 153 may be provided in the dust collection motor housing 121B. In addition, the positions of the engagement mechanism 151 and the wedge-shaped member 157 can be changed (replaced). In addition, the wedge-shaped member 157 can be disposed between the rear surface 121a of the container attachment portion 121A and the front surface 105b of the motor housing 105. In that case, the urging direction of the wedge-shaped member 157 by the compression coil spring 161 is set in the vertical direction (vertical direction), and the inclined surface 157a of the wedge-shaped member 157 is configured to contact the front surface (inclined surface) 105b of the motor housing 105. It is preferable. Further, if it is possible to secure an arrangement space, the wedge-shaped member 157 may be arranged between the upper surface 121b of the motor housing part 121B and the lower surface 105a of the motor housing 105 of the main body part 103.

  Moreover, although this Embodiment demonstrated the case where the dust collection attachment 120 was attached to the hammer drill 101, if it is a work tool which produces dust by the process operation by a front-end tool, it is applicable also to work tools other than a hammer drill. is there.

In view of the gist of the present invention, the following configuration is possible.
(Aspect 1)
"Work tool body,
A dust collecting device detachably attached to the work tool body;
A mechanical engagement portion that engages the work tool body and the dust collector in a manually releasable manner;
The work tool body and the dust collector are elastically supported between the work tool body and the dust collector in an engaged state between the work tool body and the dust collector by the mechanical engagement portion. A spacer member,
A work tool characterized in that relative rotation with respect to the work tool main body using the mechanical engagement portion of the dust collector as a fulcrum is suppressed by the spacer member.

(Aspect 2)
"A work tool according to claim 1 or aspect 1,
The mechanical engagement portion has a concave portion and a projecting portion extending in the major axis direction of the tip tool, and the concave portion and the projecting portion are fitted into each other by relative movement in the extending direction. A work tool characterized by being configured to be detached or detached. "

(Aspect 2)
“A work tool according to claim 6,
The guide grooves are provided as a pair of left and right grooves formed on the left and right side wall outer surfaces of the work tool body, and the guide rail is a pair of left and right formed on the dust collector corresponding to the pair of left and right grooves. A work tool characterized by being provided as a rail. "

(Aspect 3)
“A work tool according to claim 4,
The dust collecting apparatus has a storage box for storing the wedge-shaped member, and the storage box stores the wedge-shaped member in a state in which a part thereof protrudes from the storage box, and the protruding end portion The working tool is characterized in that an inclined surface for pressing the outer surface of the working tool body is formed. "

101 Hammer drill (work tool)
103 Main body (work tool main body)
105 Motor housing 105a Lower surface 105b Front surface 107 Gear housing 107a Front lower surface 107b Inclined outer surface 109 Hand grip 109A Battery mounting portion 109a Trigger 110 Battery pack 111 Drive motor 113 Motion conversion mechanism 115 Impact element 117 Power transmission mechanism 118 Tool holder 119 Hammer bit ( Tip tool)
119a Bit tip portion 120 Dust collection attachment (dust collector)
121 Attachment body 121A Container mounting portion 121a Rear surface 121b Upper surface 121B Dust collection motor housing portion 123 Dust collection motor 125 Suction fan 126 Dust suction opening 127 Dust collection container 128 Air exhaust port 129 Dust filter 131 Dust suction portion (dust collection portion)
133 Suction cylinder part 133a Dust inlet 133b Rear side wall part 135 Suction body part 137 Dust transfer part 137A Movable cylinder part 137B Fixed cylinder part 137b Upper surface 139 Hose 141 Connector 141A Female connector 141B Male connector 151 Engagement mechanism part 153 Guide groove 155 Guide rail 157 Wedge member 157a Inclined surface 157b Protruding portion 159 Storage box 161 Compression coil spring 163 Stopper 165 Lock mechanism 167 Lock claw 167a Inclined surface 167b on the tip side Inclined surface 169 Guide member 171 Compression coil spring 173 Lock hole 175 Unlocking member 177 Arm part 177a Inclined surface 179 Compression coil spring

Claims (8)

A work tool body;
A dust collecting device detachably attached to the work tool body;
A mechanical engagement portion that engages the work tool body and the dust collector in a manually releasable manner;
The work tool body and the dust collector are elastically supported between the work tool body and the dust collector in an engaged state between the work tool body and the dust collector by the mechanical engagement portion. A work tool comprising a spacer member. The work tool according to claim 1,
The work tool main body and the dust collector each have a first facing surface facing each other and a second facing surface facing each other, and the mechanical engagement portion is disposed on the first facing surface. The work tool is characterized in that the spacer member is disposed on the second facing surface. The work tool according to claim 2,
The work tool, wherein the first facing surface and the second facing surface are set at positions separated from each other. The work tool according to any one of claims 1 to 3,
The work tool characterized in that the spacer member is constituted by a wedge-shaped member elastically supported. The work tool according to claim 2 or 3,
The work tool, wherein the first facing surface and the second facing surface are connected via a third facing surface. The work tool according to any one of claims 1 to 5,
The mechanical engagement portion includes a guide groove extending linearly and a guide rail fitted by moving in a direction extending relative to the guide groove, and the guide with respect to the guide groove. A work tool characterized in that a fitting direction of rails and an elastic support direction of the wedge-shaped member coincide with each other. The work tool according to any one of claims 1 to 6,
A work tool comprising: a lock portion capable of locking and unlocking the engagement state in an engagement state of the work tool main body and the dust collector with the mechanical engagement portion. A hammer drill that performs a predetermined machining operation on a workpiece by rotating a tip tool mounted in a tip region of a work tool main body in a linear motion in the major axis direction and rotating around the major axis direction,
A hammer drill, wherein the work tool main body includes a dust collector attachment region that enables the dust collector according to any one of claims 1 to 7 to be attached.

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